ES1225805U - Improved amplifier of radiofrequency signals for the header system of the common telecommunications infrastructure of a building (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Enhanced amplifier of radiofrequency signals that include television or radio channels or both, for the head-end receiving system of the common telecommunications infrastructure of a building, where the amplifier comprises: - a first and a second input connector (22, 26) and a first and a second output connector (23, 27); - a distributor (21) for distributing a radiofrequency signal (211) received in the first input connector of the amplifier (22), in two signals with the same bandwidth of the radio frequency signal (211): a first signal (213) in a first outlet of the distributor and a second signal (212), with greater gain with respect to the first signal, in a second outlet of the distributor, where the first outlet of the distributor is connected to the first output connector of the amplifier (23).); - a filtering step (24) for filtering the second signal (212) comprising: - a digital analog converter (31); - a configurable digital filter (32), tuned to a frequency of a radio or television channel of the radiofrequency signal; - a digital-analog converter (34); - a broadband amplifier circuit (25) whose input (214) is the output of the filtering stage (24); - an adder circuit (28) whose output (217) is the sum of the output (215) of the amplifier circuit (25) with an external signal (216) received in the second input connector of the amplifier (26), where the output of the summing circuit is connected to the second output connector (27). (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Improved amplifier of radiofrequency signals for the header system of the common telecommunications infrastructure of a building

OBJECT AND TECHNICAL FIELD OF THE INVENTION

The present invention pertains to the technical field of radio frequency signal amplifiers. More specifically, the present invention relates to a radiofrequency signal amplifier for the header system for receiving signals from telecommunications services (for example, radio and television channels) of a building (or more generally speaking of any building) . It is important to note that the proposed amplifier is compatible with Royal Decree 346/2011 (developed in order ITC / 1644/2011) that regulates, in Spanish territory, the common telecommunications infrastructures for access to telecommunication services in the interior of the buildings.

BACKGROUND OF THE INVENTION

Common Telecommunications Infrastructure (better known by its acronym ICT) is understood as that infrastructure (set of physical networks, elements and equipment) that allows the residents of a property to access the telecommunication services provided by the operators. This infrastructure can not be any, but must meet a series of requirements or specific technical specifications, to ensure access to all services in an orderly and regulated manner.

In Spain, Royal Decree 346/2011 (developed in the norm of the Ministry of Industry, Tourism and Trade, ITC / 1644/2011) defines the regulatory regulation of common telecommunications infrastructures for access to telecommunication services in the interior of buildings (buildings). This regulation can be found on the ^website https://www.boe.es/buscar/doc.php?id=BOE-A-2011-5834. ^{Any device} designed to be part of the ICT of a building must meet the specifications of this regulation (or in other words be compatible with it).

In other words, any improvement in a device for the ICT of a building must be designed taking into account that it must comply with the specifications included in the aforementioned Royal Decree so that it can be used. And that is the first characteristic to be highlighted of the amplifier proposed in the present invention: that it fulfills the specifications of said regulation (it is compatible with it) for this type of elements.

The single-channel amplifiers are part of the common telecommunications infrastructure of a building and, more specifically, of the system or equipment of head (also called head system or equipment, or more simply "header") of reception of radiofrequency channels, RF, (for example, radio and TV channels) from terrestrial and satellite broadcasts.The head system of a building is the set of devices (amplifiers, mixers, filters, attenuators, transmodulators, converters ...) responsible for receive the RF signals coming from the different sound and television broadcasting signal (antenna) collection systems and adapt them for distribution to the user residing in the building, under the conditions of quality and quantity desired, that is, once it has been satisfactorily received the signal of the collector equipment (antenna), the task of the head system is to treat the signal, filter it, amplify it and in general, process the received signal as appropriate to adapt it to the requirements of the infrastructure or, in other words, to deliver to the exit of the header signals suitable for the network and distribution system of the building for delivery to the equipment (TV, rad io.) of the user. The single-channel amplifiers are part of said header system to amplify each RF channel separately (which may contain several programs) by providing the distribution network with the appropriate signal level to compensate for the losses that occur during distribution. The headend system will use as many single-channel amplifiers as channels to distribute. The main characteristic that these single-channel amplifiers must follow to be compatible with the regulatory regulation of ICTs (346/2011) is that the difference in level, at the exit of the head, between channels of the same nature (that is, the same type, for example, from the same transmitter), will not be greater than 3 dB. This is fulfilled by the amplifier proposed in the present invention.

The single-channel amplifiers existing to date for use in the ICT headend of a building, usually use an automix input and output technique (usually called "Z" technique, because of the way the interconnections show). between the amplifiers), so that they have two outputs and two inputs that enable the interconnection in cascade with other single-channel amplifiers (which will be responsible for amplifying other channels) of the head-end system. When one of the inputs or outputs is not used, it must be adapted with an impedance (for example, 75 ohms). The cascade of amplifiers will work as follows: 1) Each amplifier receives a signal with several channels from the front amplifier of the cascade in its first input (in the case of the first amplifier of the cascade of amplifiers, this signal will be the signal coming from of the signal collector equipment such as the antenna); 2) the amplifier filters to its interior only the desired channel and also delivers that same received signal in its first input with all the channels through its first output, to the first input of the next amplifier of the cascade; 3) the amplifier amplifies the filtered channel, and in the output stage mixes it with the channels filtered and amplified by the other amplifiers of the headend (received in its second input) and delivers them on its second output to the second input of the next waterfall amplifier.

To do this, the existing single-channel amplifiers typically consist of 3 stages (as can be seen in Figure 1):

- One entry stage (11). Said input stage has as input a signal (111) in which several channels are present, which is received by the first input connector 12 of the amplifier of the previous amplifier of the cascade (or from the antenna if it is the first amplifier of the cascade). the waterfall). In the example of figure 1, for simplicity only 5 channels, 25, 28, 30, 36 and 41 are shown from the received signal (this is only a non-limiting example). This stage consists of two connectors (first input connector 12 and first output connector 13 of the amplifier), one at the input and one at the output of the stage that serve to make a "loop through" or cascade (these connectors use the Z technique to perform the cascade so they are called "Z" connectors). This step is implemented by means of a cavity filter adjusted to the desired channel (36 in the case of figure 1), so that only the desired channel (terrestrial, satellite or whatever) is in the output signal (112) that enters the next stage; in turn the signal received with several channels is propagated (113) to the next amplifier of the cascade (through the first output connector 13). In the case shown in figure 1, only channel 36 (desired channel) is delivered to the next stage (14) and all channels (25, 28, 30, 36 and 41) continue through the output connector (13). ) that are delivered to the next cascade amplifier.

- The second stage (14) is a fixed gain amplifier, with an integrated variable loss attenuator, in order to be able to adjust the amplifier to the desired gain.

- Finally, an exit stage (15). Said output stage consists of two connectors, (second input connector 16 and second output connector 17 of the amplifier), one to the input and one to the output of the stage that serve to make a "loop through" or cascade. stage receives a signal (114) with the desired amplified channel of the second stage (14) and also receives, through the second input connector of the amplifier 16), a signal (115) with several amplified channels, coming from the previous amplifier of the cascade (if it is the first amplifier of the cascade will not receive any signal through this second connector.) In the case of figure 1 said channels amplified in previous stages of the cascade, would be channels 25 and 28.

This step is also performed by a filter of cavities adjusted to the desired channel, so that only the adjusted channel is added to the signal with the rest of channels (115) present in the second input connector of the Z, and whose sum ( 116) is carried to the output connector 17. The objective of this stage is not only to filter, but to add the input of the output stage, to the channel that has been processed, avoiding that the rest of channels (in signal 115) pass inside the amplifier equipment.

In the headend there is usually a single-channel amplifier for each RF channel that is to be distributed, each amplifier tuned to the frequency of a channel. These mono-channel amplifiers are connected in series (normally using the Z-technique shown above) so that the output of one connects with the input of the next the input of the other, so that each of them filters and amplifies a certain channel ( to the which is tuned) and mixes its signal with those previously amplified by the amplifiers of previous channels. The input of the first single-channel amplifier of the series, will be the signal received from the antenna or antennas, with all the channels. When the channel offer is extended (for example, a new chain is issued), a new single-channel amplifier module must be inserted in the header.

The single-channel amplifier used to date (as defined in the previous paragraphs) has several advantages over broadband amplification:

- Amplifies a specific TV channel, without affecting the rest of the band.

- It has a high selectivity (capacity of the amplifier to reject the channels adjacent to the desired one, that is, to the channel that must amplify) that allows to equalize each channel, in an independent way.

- The use of a separate amplifier for each channel greatly reduces the intermodulation products that can be generated in other types of amplifiers such as broadband

- It allows to regulate the gain of each channel in a completely individualized way, and equalize.

However, these single-channel amplifiers also have important drawbacks, such as, among others:

- Instability of the filters with temperature and aging.

- Each channel requires a particular setting, and therefore a different model of amplifier per channel is necessary.

- The selectivity is high but often not enough to treat adjacent channels efficiently

For all the aforementioned, there is a need for a single-channel amplifier compatible with the regulatory regulation of mandatory compliance, which resolves the problems and disadvantages of the used single-channel amplifiers at present.

SUMMARY OF THE INVENTION

The present invention proposes a single-channel amplifier of radiofrequency signals for the head-end system for receiving signals from telecommunications services (for example, radio and television channels) of a building, compatible with the requirements set forth in Royal Decree 346/2011 that regulates, in Spanish territory, the common telecommunications infrastructures inside the buildings.

The proposed amplifier solves the drawbacks of the single-channel amplifiers of the state of the art cited above, presenting at least the following advantages over them:

- A single amplifier model (ie, a single type of amplifier equipment) is capable of processing any channel of the input signal band (for example, in the VHF / UHF band), without having to adjust it in the factory for each channel or for a width.

- When doing a digital filtering, eliminates the drift with the temperature of the existing amplifiers.

- In addition, these advantages are achieved, complying with the difference in level, at the output of the amplifier, not exceeding 3 dB for channels of the same nature, which requires the current regulation, since an independent filtering is performed for each channel.

- Its greater selectivity and its output in broadband allows working in adjacent channel with greater guarantees.

In a first aspect, the present invention describes an improved amplifier of radiofrequency signals that include television or radio channels or both, for the head reception system of the common telecommunications infrastructure of a building (building), where the amplifier comprises :

- a first and a second input connector and a first and a second output connector; - a distributor to distribute a radio frequency signal received in the first input connector of the amplifier, in two signals with the same bandwidth of the radio frequency signal: a first signal in a first outlet of the distributor and a second signal, with greater gain with respect to the first signal, at a second outlet of the distributor, where the first outlet of the distributor is connected to the first output connector of the amplifier;

- a filtering step for filtering the second signal comprising:

- a digital analog converter;

- a digital filter, tuned to a frequency of a radio or television channel of the radiofrequency signal;

- a digital-analog converter;

- a broadband amplifier circuit whose input is the output of the filtering stage;

- an adder circuit whose output is the sum of the output of the amplifier circuit with an external signal received at the second input connector of the amplifier, where the output of the summing circuit is connected to the second output connector.

The input radio frequency signal may be a broadband signal in the UHF and / or VHF band.

The summing circuit (mixer) can be a directional coupler, for example, a printed circuit made of printed lines "microstrip".

In the digital filter, at least one of the following characteristics can be configured: channel to be filtered and its gain. For example, by means of a DIP switch or a multiple switch. The filter width of the digital filter will preferably be that of a radio or television channel of the radio frequency input signal. The filtering stage can have several digital filters, tuned to frequencies of different channels (consecutive or not) of the radio frequency input signal.

For a more complete understanding of the invention, its objects and advantages, reference may be made to the following specification and the accompanying drawings.

DESCRIPTION OF THE DRAWINGS

To complement the description that is being made and in order to help a better understanding of the characteristics of the invention, according to preferred examples of practical embodiments thereof, an assembly of drawings is included as an integral part of this description. where, with illustrative and non-limiting character, the following has been represented:

Figure 1 shows a block diagram of the architecture of a single-channel amplifier, according to an embodiment of the state of the art.

Figure 2 shows a block diagram of the architecture of a single-channel amplifier, according to an embodiment of the invention.

Figure 3 shows a block diagram of the architecture of the filtering stage of a single-channel amplifier, according to an embodiment of the invention.

Figure 4 shows a diagram of the printed microstrip lines used in the output stage of a single-channel amplifier, according to an embodiment of the invention.

DETAILED DESCRIPTION OF THE INVENTION

The present invention proposes an improved amplifier for use in a head system (for example, for the reception of radio and television channels) of a building, compatible with the requirements for common telecommunications infrastructures inside buildings, in force in Spanish territory.

The proposed single-channel amplifiers use an automix technique of input and output, so that they have two outputs and two inputs that enable cascade interconnection with other single-channel amplifiers such as the one proposed (which will be responsible for amplifying other channels) of the head-end system (usually called the "Z" technique, because of the way the interconnections between the amplifiers show.) As will be explained below, the components of the amplifiers and the signals that are exchanged between the amplifiers of the cascade are different from the amplifiers. of the state of the art.

Specifically, the proposed amplifier consists of 4 stages (as you can see in Figure 2):

1. Input stage (21): This stage works as a distributor (active), that is, what it does is distribute the radio frequency signal that is at the entrance (211) in two signals that will have the same characteristics as the entrance sign; only one of them (213) will have a power level similar to that received at the input (and this signal will be the one that leaves through the first output connector 23) and the other (212) will have a slight gain with respect to the level power of the input signal (and this signal will be the one that is delivered to the next stage of the amplifier).

In an embodiment, said input stage has as input a broadband signal (211) in which several channels are present (generally speaking all the channels received by the header), which is received by the first input connector 22. Dicha The signal can be, for example, coming from the previous amplifier of the cascade if there is one or coming from the antenna or antennas if it is the first amplifier of the cascade. In the example of figure 2, for simplicity only 5 channels, 25, 28, 30, 36 and 41 of the received signal are shown (this is only a non-limiting example). The signals drawn in different points of the figures 1 and 2 is only a way to visually indicate the channels in each point of the represented scheme, it does not mean that the power or the form of the signals have to be as they are drawn in said figures . In a preferred embodiment, the input signal will be in the ultra high frequency (UHF) band or in the very high frequency (VHF) band, since it will be a signal with television and radio channels, but this is only one embodiment and the present invention can be applied in any other frequency band, so in other embodiments the input signal can be an RF signal in other frequency bands other than UHF or VHF. This stage consists of two connectors (first input connector 22 and first output connector 23 of the amplifier), one at the input and one at the outputs of the stage that serve to make a "loop through" or cascade with other amplifiers (The Z technique is usually used to perform the cascade, so they are called "Z" connectors).

In this first stage of the proposed amplifier no filtering is carried out; that is, the signal that is given to the second stage of the amplifier and that which is given to the first output connector 23 (and hence, for example to the next amplifier of the cascade) contains all the channels of the input signal. The signal 213 (which is delivered to the first output connector 23) will have a power level similar to that which it receives at the input (it can at most have a small gain, for example 0.5 dBs). The signal 212 (which is delivered to the next stage of the amplifier) usually has somewhat more gain (eg, 6 dBs) with respect to the power level of the input signal.

2. Selective filtering stage (24): An example of a possible embodiment of this step is shown in Figure 3. The analog signal of radio frequency input 212 (for example, in the VHF or UHF band) is passed through an analog-digital converter 31 (ADC) to obtain the corresponding digital signal, said digital signal is passed to a digital filter (32) at the desired channel width (for example, terrestrial). In other words, a signal is digitized in the entire input band (UHF or VHF), and digitally filtered to the width of the terrestrial channel.This digital filter optionally consists of an automatic gain control (CAG) that allows you to maintain the level of your output independent of the input level This digital filtering is performed with a selectivity much higher than that achieved with the cavity filters, and compatible with the current ICT regulation.

In a preferred embodiment there will be a single digital filter. In other embodiments instead of just one, several digital filters (two, three or any other number, for example, four in the case of Figure 3), each one responsible for filtering a different channel may be used since at this stage the signal arrives with all the channels of the entrance. In those cases, you would not have a single-channel amplifier itself but a two-channel, three-channel, or four-channel amplifier, in which the same solution is given to several channels at the same time. Although this amplifier with several filters, can also be seen as several single-channel amplifiers implemented in a single element, which saves resources. In one embodiment, several filters can be included in the amplifier and the user can choose between using several of them (if he wants to process several channels at the same time) or only one, if he wishes.

In one embodiment, the channels filtered by each of the filters may be consecutive while in other embodiments they may not be.

The digital channel filter is configurable (programmable) by the user, for the specific use he wants to make of it. So the user can choose, the specific channel to be filtered, his profit ...,. It can even be done that instead of an amplifier unit per channel, two, three, or as many channels are filtered (normally a maximum of 32 per chip). In an embodiment (for example, in the amplifier proposed in Figure 3), there will be the possibility of 1 to 4 channels (this is only an example, and any other number of channels and therefore of filters, is possible), being an individual filtering for each channel, so that one or more channels can be processed in the same amplifier equipment without loss of quality in the selectivity of each of the channels and equalized in power at the output, while in traditional single-channel amplifiers , when working in the multi-channel bandwidth mode, the characteristics of the filtering and equalization of the input are transferred to the output, which would not meet the equalization requirements set by the ICT (3dBs at the output). , regardless of the entry. In other words, in traditional single-channel amplifiers doing this (processing several channels at the same time) supposed a loss of performance, however in the amplifier proposed by the present invention, there is no loss of performance since the filtering characteristics are maintained and it is possible to perform an equalization.

To make the digital filter configurable / programmable by the user, any of the known solutions for configurable circuits can be used. For example, you can use a DIP switch (in English "DIP switch"). This element consists of a set of electrical switches that are encapsulated together (for example, in a double row package, Dual In-Line Package in English , which stands for the name of DIP for this element.) That is, the DIP switch, although it is called as a DIP switch in the singular, refers to a set of switches encapsulated together.This type of switch is commonly used to modify or customize the hardware behavior of the electronic device in which this switch is used for certain specific situations In the case of the proposed amplifier, the DIP switch allows the user to configure the specific characteristics of each digital filter used in the amplifier (concrete channel to be filtered , its gain, width of the filter.) The fact that the amplifier is configurable by each user for the specific use that and wants to make it, allows the same type of amplifier can be used in many different scenarios / cases without having to come from the factory implemented for a specific use; in other words a single computer is capable of processing any channel in the band frequency of entry, which implies a huge saving of resources in the manufacture of these amplifiers (since the same amplifier is manufactured for a multitude of different cases).

Once the digital filtering has been carried out, with a selectivity much higher than that achieved with the cavity filters, and compatible with the current ICT regulation, it is passed to a digital-analog converter 34 (DAC, from the English "Digital-Analogical Converter). , which passes the signal back to the analog domain to deliver said signal (214) to the next stage.In the case that there is more than one digital filter, the output signals would be multiplexed (33) to deliver a single multiplexed signal to the DAC (3. 4).

3. Amplification stage (25): This is a step of amplification in the whole band of the input signal (for example, VHF / UHF). The intermodulation products that appear in this amplification will be similar to those of the traditional single-channel amplifier, since the previous stage has left a very selective signal (that is, with a high selectivity). This stage does not amplify for a specific channel but amplifies the whole band, so this stage does not depend on (does not vary with) the channel (or channels) that has been filtered in the previous stage (yes, as the input signal to this amplifier has previously been filtered to a specific channel then the output signal of this amplifier will also be limited to that channel, but not because the amplification is limited to a specific channel).

4. Output stage (28): Said output stage consists of two connectors, (second input connector 26 and second output connector 27 of the amplifier), one to one of the inputs and the other output of the stage that serve to "loop through" or cascade This stage receives the desired amplified channel (215) of the third stage (25) and can also receive, through the second input connector of the amplifier 26, an external signal (216) with several amplified channels (in one embodiment, said external signal can be from the second output of the previous amplifier of the cascade, if it is the first amplifier of the cascade it will not receive any signal through this second connector and it would have to be charged, for example with a load of 75 ohms.) In the case of figure 2, said channels would be channels 25 and 28 (this is only an example, not limiting).

This step adds the signal from the previous stage 215 (desired amplified channel) with the external signal (216) present in the second input connector of the Z (26), and said sum (217) is carried to the output connector of the amplifier 27 (for example, for delivery to the second input of the next amplifier of the cascade, if there are no more amplifiers, this would be the output of the amplifier set).

In a preferred embodiment for this step, a directional coupler made from printed (power transmission) lines of the "microtira" type (better known by its English "microstrip") is used. This ensures that any frequency processed within the working band of the amplifier (for example, VHF / UHF) can go outside and add to the existing ones in the most efficient way possible. This directional (passive) coupler has the advantage that it makes possible the mixing of the signal processed by the equipment of the present invention (output of the amplification stage, 215) with an existing external signal (for example, from the previous amplifier). the cascade), obtaining very low losses in said mixture for the external signal (signal 216, which enters through the second input connector 26).

Figure 4 shows a possible example of the printed circuit circuit proposed for this directional coupler (Figure 4 presents only one non-limiting example and other dimensions and shapes are possible). This coupler adds (mixes) the signal that enters through the input of the loop 41 (signal 216) with the signal coming from the previous stage of the amplifier at the input 42 (signal 215), giving the output 43 the mixture of both signals ( sign 217); having the advantage that it performs said mixing with very low losses for the signal (216) that comes through the input 41. The external signal to be mixed (216) enters through the point 41 (second input connector of the amplifier 26) and outputs by the point 43 (second output connector of the amplifier 27), in the example presented in figure 4 with a loss of less than 0.5 dBs. The signal after going through all the stages of the equipment proposed in the present invention (output of the amplification stage, 215) is injected into the second input 42, from this point to the output (43) there are obtained losses of about 12-13 dBs in the example presented in figure 4.

However, the attenuation / protection that occurs between the input signals of the coupler, ie between the external signal to be mixed (216) that enters through the input 41 of the coupler and the signal coming from the previous stage (215) that enters by the input 42 of the coupler, it is much larger. Thus, in the usual working frequencies (for example, 470 MHz or 860MHz) there is an attenuation of more than 32 dBs, in this concrete example. The greater the attenuation, the greater the protection towards the amplifier equipment, so that in this way it is not affected by the signals existing in the mixture.

In this text, the term "comprises" and its derivations (such as "understanding", etc.) should not be understood in an excluding sense, that is, these terms should not be interpreted as excluding the possibility that what is described and defined can include more elements, stages, etc.

Some preferred embodiments of the invention are described in the dependent claims which are included below.

Having sufficiently described the nature of the invention, as well as the manner in which it is carried out in practice, it is necessary to state the possibility that its different parts may be manufactured in a variety of materials, sizes and shapes, and it may also be introduced in its constitution or procedure, those variations that the practice advises, as long as they do not alter the fundamental principle of the present invention.

The description and the drawings simply illustrate the principles of the invention. Therefore, it should be appreciated that those skilled in the art will be able to devise various provisions which, although not explicitly described or shown in this document, represent the principles of the invention and are included within its scope. In addition, all the examples described in this document are provided primarily for pedagogical reasons to help the reader understand the principles of the invention and the concepts contributed by the inventor (s) to improve the technique, and should be considered as non-limiting. with respect to such examples and conditions described specifically. In addition, everything set forth in this document related to the principles, aspects and embodiments of the invention, as well as the specific examples thereof, encompass equivalences thereof.

Although the present invention has been described with reference to specific embodiments, those skilled in the art should understand that the foregoing and various other changes, omissions and additions in the form and detail thereof may be made without departing from the spirit and scope of the invention. the invention as defined by the claims next.

Claims (8)

1. - Improved amplifier of radiofrequency signals that include television or radio channels or both, for the head-end receiving system of the common telecommunications infrastructure of a building, where the amplifier comprises: - a first and a second input connector (22, 26) and a first and a second output connector (23, 27); - a distributor (21) for distributing a radiofrequency signal (211) received in the first input connector of the amplifier (22), in two signals with the same bandwidth of the radio frequency signal (211): a first signal ( 213) in a first outlet of the distributor and a second signal (212), with greater gain with respect to the first signal, in a second outlet of the distributor, where the first outlet of the distributor is connected to the first output connector of the amplifier (23). ); - a filtering step (24) for filtering the second signal (212) comprising: - a digital analog converter (31); - a configurable digital filter (32), tuned to a frequency of a radio or television channel of the radiofrequency signal; - a digital-analog converter (34); - a broadband amplifier circuit (25) whose input (214) is the output of the filtering stage (24); - an adder circuit (28) whose output (217) is the sum of the output (215) of the amplifier circuit (25) with an external signal (216) received in the second input connector of the amplifier (26), where the output of the summing circuit is connected to the second output connector (27). 2. - Amplifier according to claim 1, wherein the input radio frequency signal (211) is a broadband signal in the UHF and / or VHF band. 3. Amplifier according to any of the preceding claims, wherein the adder circuit (28) is a directional coupler. 4. Amplifier according to claim 3, wherein the directional coupler is a printed circuit made of printed lines "microstrip". 5. - Amplifier according to any of the preceding claims wherein in the digital filter (32) are configurable at least one of the following characteristics: channel to be filtered and its gain. 6. - Amplifier according to claim 5, wherein the digital filter (32) includes a DIP switch to be configurable by the user. 7. - Amplifier according to any of the preceding claims, wherein the filter width of the digital filter (32) is that of a radio or television channel. 8. - Amplifier according to any of the preceding claims wherein the filtering step (24) contains several configurable digital filters (32) tuned to frequencies of different channels of the radio frequency signal (211).